Inhalation device for powdered drugs

ABSTRACT

The invention refers to an inhalation device for powdered drugs to be received by a patient by an inhalation-caused air stream, comprising at least one powder reservoir, metering means for repeatedly metering a powder dose from the reservoir, a transportation mechanism for moving said metering means from a filling position for receiving a powder dose into an emptying position for releasing said powder dose into a powder channel, at least one activating device for manual operation by the patient being operatively connected to said transportation mechanism such that upon operation a single powder dose is being metered, said activating device comprising a dosage key ( 5 ) acting on said transportation mechanism when actuated by the patient. According to the invention, said transportation mechanism furthermore comprises a dosage lever ( 6 ) acting on said metering means, said dosage lever ( 6 ) being locked in the inhalation position of said metering means after said dosage key ( 5 ) has been properly pressed down by the patient. The dosage lever ( 6 ) in the inhalation position engages a trigger member and is releasable by actuation of the trigger member. The trigger member comprises at least one cam surface and the dosage lever ( 6 ) engages the cam surface tangentially in said locked inhalation position.

The invention refers to an inhalation device for powdered drugs to be received by a patient by an inhalation-caused air stream, comprising at least one powder reservoir, metering means for repeatedly metering a powder dose from the reservoir, a transportation mechanism for moving said metering means from a filling position for receiving a powder dose into an emptying position for releasing said powder dose into a powder channel, and at least one activating device for manual operation by the patient, said activating device being operatively connected to said transportation mechanism such that upon operation a single powder dose is being metered, said activating device comprising a dosage key acting on said transportation mechanism when pressed by the patient.

A powder inhaler of above-referred kind is for instance disclosed in EP 1 616 592 B9.

In the field of treating bronchial diseases but also other diseases in which medication can be affected by way of the respiratory tract, it is generally known to apply medicaments in powder form. Of course, in the art are also known devices for atomization of solutions of suspensions to provide inhalable aerosols.

The present invention relates to an inhaler for the administration of powdered pharmaceuticals in form of a multi-dose dry powder inhaler, preferably with a dosing counting or indexing means provided in the inhaler or on a cartridge for powdered pharmaceuticals.

As aforementioned, an inhaler of this kind is disclosed in EP 1 616 592 B9. This reference refers to an inhaler for providing a large number of doses of a pharmaceutical powder medicament from a single reservoir space which medicament can be received by the patient by means of an air stream which has to be induced by suction to a mouthpiece by the patient.

For multi-dose inhalers an important design aspect is the metering accuracy of the device.

Another important design aspect of inhalation devices of the above-referred kind are the use properties of the device.

The inhalation device has to be designed such that the user clearly may make out whether the device is ready for inhalation, and whether the device has a certain and sufficient residual amount of powder doses. Moreover, the device has to be sufficient fail-safe and safe against operating errors of the user. For instance double dosing has to be prevented in any event by an appropriate design of the metering technique.

In particular, EP 1 616 592 B9 refers to a locking mechanism, locking an activation device and/or transportation mechanism of the inhaler after a pre-determined number of metering cycles.

This known inhalation device comprises an activating device for manual engagement by the patient for repeatedly metering a dose of medicament to be administered to the patient, an advancing mechanism for advancing a counting or indexing means each time the activating device has been engaged by the patient so that a dose of medicament has been released for administration to the patient, the counting or indexing means comprises an index, the index being detectable by a detection means of the inhaler, and the detection means being coupled to a locking mechanism, the locking mechanism blocking the activation device and/or any transportation mechanism of the inhaler delayed by a pre-determined number of metering cycles since detection of the index. The activating device is arrested in a position different from the operating position indicating the blocking state of the inhaler. This arrangement allows to block further use of the inhaler after removal of a number of doses from the reservoir space or an approximate number of doses left in the reservoir space with a simple, inexpensive and reliable mechanism so that an improved security of the patient using the inhaler can be obtained. In this manner, a patient is prevented from trying to dose from an empty reservoir space causing an inappropriate lack of required medicine. Insofar, the known inhalation device provides an enhanced usability.

WO 2008/077623 A1 discloses an inhalation device for powder drugs comprising at least one storage chamber for accommodating a plurality of drug powder doses and a dosing device which includes at least one dosing slider which is moveable with a translatory movement in a dosing slider passage from a filling position into an emptying position, wherein the inhalation device further includes a device for inhalation-triggered automatic movement of the dosing slider from its filing position into the emptying position and a return device for automatic movement of the dosing slider back into the filling position. The device for inhalation-triggered automatic movement of the dosing slider comprises a pivotally mounted spring-loaded flap arranged into an air passage. The spring-loaded flap cooperates with a thrust rod which releases the device for inhalation-triggered automatic movement of the dosing slider when the flap is deflected out of its rest position by an airflow through the air passage upon inhalation by the patient. This requires a predetermined minimum airflow in the air passage to be exceeded. For comprehensive moisture protection for the medicament in the storage chamber of the cartridge, the inhalation device according to WO 2008/077623 A1 includes a dosing slider passage which has a corresponding opening at its open ends to which the dosing slider can issue with the dosing cavity, wherein a contact surface or a seal is provided around the opening and wherein the dosing slider further has a sealing surface, which is arranged in a plane approximately transverse relationship with the direction of movement out of the filling position into the emptying position. The sealing function may be provided by elastic seal disposed on the contact surface of a sealing surface of the dosing slider. These sealing measures, however, do not contribute to the issue of reproducible triggering forces.

It is generally desirable to have a defined trigger threshold for accomplishing such inhalation-triggered automatic movement of the dosing slider. It will be readily apparent for a person skilled in the art that a certain bandwidth for the required triggering forces, i.e. a certain air flow variation for the suction to be applied by the patient is unavoidable due to the tolerances of the moveable parts of such an inhaler.

U.S. Pat. No. 6,071,498 discloses an inhalation device for powdered drugs with prevention means for double or repeated dosages. The device contains a powder reservoir, metering means for repeatedly metering a powder dose from the reservoir, a transportation mechanism from moving said metering means from a filling position for receiving a powder dose into an emptying position for releasing said powder dose into a powder channel, a dosage key, acting on said transportation mechanism when pressed by the patient, said transportation mechanism comprising a dosage lever acting on said metering means, wherein said dosage lever is locked in the inhalation position of said metering means after said dosage key has been actuated by the user. In the locked position, the dosage lever is engaged with a catch hook in a recess with a blocking edge in the shaft of a flap valve functioning as a trigger member. The engagement of the metering lever/dosage lever with its catch hook in the recess is released by moving the flap valve by means of the air stream caused by inhalation with little delay, so that the metering lever is pulled back into its initial position under the load of springs. The position of the catch hook within the recess generally determines the position of the contact point of the catch hook relative to the blocking edge of the recess. Depending on the mounting tolerances of the metering lever and the flap valve as the moving parts of the inhaler, the contact point between the catch hook and the blocking edge within the recess may have a different position which actually results in more or less delay between inhalation by the user and release of the flap valve. A contact point between the catch hook of the metering lever within the recess may be very close to the blocking edge with the result that release of the flap valve occurs almost instantaneously after the flap valve starts a pivoting movement. On the other hand, the contact point between the catch hook and the metering lever within the recess may be relatively far away from the blocking edge in the shaft so that upon pivoting movement of the flap valve, there is a certain delay until the metering lever is ultimately released. In effect, this requires higher triggering forces as in the first case.

However, it is desirable to keep the triggering forces for inhalation-triggered automatic metering as reproducible as possible. Such defined trigger threshold ultimately results in a more constant volumetric flow during inhalation so that for instance if the powder medicament to be received is in the form of an adhesive mixture, the dry powder will be more effectively deagglomerated for releasing the drug particles from the powder formulation. In effect, the dosing accuracy increases.

It is therefore an object of the present invention to provide an inhalation device in which at least a part of the metering cycle is inhalation-triggered and in which the bandwidth for the required triggering forces is as small as possible.

Moreover, it is an object of the present invention to provide an inhaler of the above-referred kind which is further enhanced with regard to usability and in view of eventual mal operation. This and other objects are achieved by an inhalation device according to claims 1 and 10. Advantageous embodiments of the invention may be derived from the dependent claims.

According to one aspect of the present invention, there is provided an inhalation device for powdered drugs to be received by a patient by an inhalation-induced airflow, comprising at least one powder reservoir, metering means for repeatedly metering a powder dose from the reservoir, a transportation mechanism for moving said metering means from a filling position for receiving a powder dose into an emptying position for releasing said powder into a powder channel, at least one activating device for manual operation by the patient, being operatively connected to said transportation mechanism such that upon operation a single powder dose is being metered, said activating device comprising a dosage key acting on said transportation mechanism, wherein said transportation mechanism comprises a dosage lever acting on said metering means, said dosage lever locked in the inhalation position of said metering means after said dosage key has been properly actuated and wherein said dosage lever in the inhalation position engages a trigger member and being releasable by actuation of the trigger member, wherein the trigger member comprises at least one cam surface and wherein the dosage lever engages said cam surface tangentially in said locked inhalation position.

With the inhalation device according to the invention, the metering cycle will only be completed and the transportation and/or metering means will only be reset after inhalation of a metered quantity of powder by the patient. Inhalation will cause the trigger member to release said dosage lever which will reset the metering means into its filling/receiving position. Since the dosage lever only engages said cam surface of the trigger member tangentially, the contact force between the dosage lever and the trigger member is almost independent from the tolerance of the components.

In other words, the trigger member comprises a cam surface which forms a curve which is engaged or contacted by the dosage lever peripherally from outside such that the fastening hook makes line contact with the cam surface. The position of the contact point/contact line between cam surface and the dosage lever is almost the same, i.e. remains stable, irrespective of the angular end position (locked position) of the trigger member relative to the dosage lever.

According to one advantageous aspect of the invention, the trigger member comprises an inhalation-operated valve in an air duct communicating with said powder channel. The inhalation-operated valve is operatively connected to said dosage lever so that the dosage lever is releasable by action of the valve initiated by the suction generated by the patient during inhalation. The inhalation-operated valve may be for instance in the form of a spring-loaded flap which due to the resilience of the spring is normally held in closed position.

The dosage lever may comprise a fastening hook engaging behind and/or under said cam surface in the inhalation position.

In one advantageous embodiment of the inhalation device according to the invention, the fastening hook comprises a planar contact surface making line contact with the cam surface in the inhalation position. Due to the fact that the fastening hook only tangentially engages the cam surface, excursion of the contact surface due to the tolerances of the parts of the inhaler is only possible in axial direction, which, however, has no impact on the required triggering forces.

Triggering of the dosage lever is achieved by a pivot motion of the cam surface so that only a slight pivoting movement of the triggering member almost instantaneously releases the dosage lever. Due to this design, the bandwidth of required air flow variation for the suction to be applied by the patient can be kept remarkably below 30 l/min.

In one advantageous embodiment, the inhalation-operated valve may include a flap which fulfils a pivot movement upon inhalation, said cam surface being provided on the flap or on a pivot shaft of the flap. The flap is for example a major component of the aforementioned valve. The pivot axis may extend in the centre of gravity of the flap or nearby the centre of gravity of the flap. In the event the cam surface is also arranged nearby the pivot axis or nearby the centre of gravity of the flap, easy triggering may be achieved.

According to yet another aspect of the present invention, there is provided an inhalation device for powder drugs to be received by a patient by an inhalation-caused air stream/inhalation-caused air flow, comprising at least one powder reservoir, metering means for repeatedly metering a powder dose from the reservoir, a transportation mechanism for moving said metering means from a filling position for receiving a powder dose into an emptying position for releasing said powder dose into a powder channel, at least one activating device for manual operation by the patient, said activating device being operatively connected to said transportation mechanism such that upon operation a single powder dose is being metered, said activating device comprising a dosage key acting on said transportation mechanism when pressed by the patient, and at least one powder disintegration means, wherein said metering means and said transportation means are arranged within a dosing compartment and said disintegration means is arranged in a powder discharge compartment, and wherein said dosing compartment is sealed against said powder discharge compartment.

A powder disintegration means in the sense of the instant application is a means for breaking up a powder agglomerate or releasing drug particles from a carrier material. Said powder disintegration means may include means for guiding powder and air as well as a cyclone/air classifier.

Sealing the dosing compartment of the inhaler relative to said powder discharge compartment also remarkably reduces the variation in required air flow for triggering. Accordingly, this design avoids the possibility of sucking an airflow through the inhaler which by-passes the powder channel and/or an air duct of the device.

In one advantageous embodiment, the inhalation device according to the invention further comprises a main structural support member defining a valve chamber as well as support for a housing including at least two shells.

In a preferred embodiment, the valve chamber is sealed against the housing so as to define said dosing compartment and said powder discharge compartment.

A seal may be provided in the form of a resilient lip extending completely around the valve chamber in an uninterrupted fashion.

Alternatively, the sealing between the dosing compartment and the powder discharge compartment may be provided in form of a labyrinth seal. The valve chamber may comprise a rigid sealing rib extending completely around the valve chamber and engaging corresponding sealing grooves within the shells of the housing so as to form a labyrinth.

In the following the invention is disclosed by way of example with reference to accompanying drawings in which:

FIG. 1 shows a perspective view of an embodiment of an inhalation device according to the invention with the mouthpiece cap opened,

FIG. 2 shows an exploded view of the inhaler according to the invention,

FIG. 3 shows a partial longitudinal cross-sectional view through an inhaler according to a first embodiment of the invention,

FIG. 4 shows another longitudinal cross-sectional cut through the inhaler according to the first embodiment of the invention,

FIG. 5 shows a perspective view of a dosage key according to the invention,

FIG. 6 shows a cross-sectional view of the inhaler in a non-actuated state of the dosage key,

FIGS. 7 a, 7 b show a cross-sectional view corresponding to the view shown in FIG. 6 where the dosage key is partially pressed,

FIG. 8 a shows a cross-sectional view according to FIGS. 6 and 7 where the dosage key is fully depressed,

FIG. 8 b shows a perspective view demonstrating the engagement of the dosage lever into the flap valve,

FIG. 9 shows a perspective view of a dosage lever of the inhaler according to the present invention,

FIG. 10 shows a perspective view of a first preferred embodiment of an inhalation-operated valve closing the air duct of the inhaler according to the invention,

FIG. 11 a shows another perspective view of the inhalation-operated valve according to FIG. 10,

FIG. 11 b shows a perspective rear view of an inhalation-operated valve according to a second preferred embodiment,

FIG. 12 shows a perspective side view of the inhaler according to the invention without its housing,

FIG. 13 shows an enlarged detail of FIG. 12 as a rear view,

FIG. 14 a shows an enlarged detail of the engagement between the dosage lever and an inhalation-operable flap valve of the inhaler according to a first preferred embodiment of the invention,

FIG. 14 b shows an enlarged detail of the engagement between the dosage lever and the flap valve according to the first preferred embodiment,

FIG. 14 c shows an enlarged detail of the engagement between the dosage lever and the flap valve according to a second preferred embodiment,

FIG. 15 shows another longitudinal sectional view through the inhaler,

FIG. 16 shows a perspective view of a powder cartridge of the inhaler according to the invention,

FIG. 17 shows a perspective view of the inhaler housing,

FIG. 18 shows a detail of the counter slide gliding over the counter ring's tooth,

FIG. 19 shows a detail of the cartridge's locking ratchet (locking lever not displayed),

FIG. 20 shows a detail of the locking lever and its engagement with the dosage key and the counter ring.

The inhaler 1 shown in FIGS. 1 to 20 is an inhaler for powdered medicaments, for providing a large number of doses of a pharmaceutical powder medicament from a receptacle in the form of a powder cartridge. The powder cartridge 3 defines a reservoir 2 for receiving a large number of doses of a pharmaceutical powder/powdered drug. In the described embodiment, the typical number of doses which may be obtained from one powder cartridge 3 may be in the range of 30 to 60 doses.

The reservoir 2 is sealingly covered by a lid 4 as can be seen from FIG. 2. The lid is secured to the cartridge body 3 a in the assembled state of the inhaler in a non-removeable fashion.

The powder medicament can be received by a patient by means of an air stream caused by the user, i.e. induced by suction. Therefore, the inhaler further comprises an activating device for manual engagement by the patient in the form of a dosage key 5 being connected to a transportation mechanism including a dosage lever 6 and a locking lever 7. The dosage lever 6 acts on a dosage slide 8 as a metering means being moveable from a filling position for receiving a powder dose into an emptying position for releasing said powder dose into a powder groove 16 a of a cyclone 16 for deagglomeration of the powder in the cyclone 16. From the powder groove 16 a the patient can inhale the powdered drug through a mouthpiece 10 via an air stream generated by the patient. If not in use, the mouthpiece 10 is protected from dirt by a mouthpiece cover 11. The mouthpiece cover 11 is secured to the inhaler housing fixedly, i.e. non-detachable.

The powder groove 16 a of the cyclone 16 forms a part of a powder channel through the cyclone 16 which functions as a disintegration means as this is known from the art. The powder medicament to be received by the patient may be in form of an adhesive mixture. Adhesive mixtures consist of relatively large crystals, generally α-lactose-monohydrid, carrying the micronised drug particles on their surface. In the disintegration system, the dry powder will be deagglomerated for releasing the drug particles from the powder formulation. The cyclone 16, i.e. the disintegration means, generally includes an air circulation chamber as well as several air supply channels which enter the circulation chamber tangentially so that a circular air flow pattern is created inside the circulation chamber. So the total respiratory flow through the inhaler does include a transportation airflow for traversing the powder dose in the powder groove and dragging the powder into the circulation chamber, a cyclone air flow which tangentially enters the circulation chamber as well as eventually a bypass airflow for creating a so-called sheath flow of clean air. A possible design for the disintegration means is for instance disclosed in the international patent publication WO 03/000325 the disclosure of which is herewith fully incorporated by reference. The disintegration means in the following in a rather simplified form is referred to as a cyclone. In a also rather simplified form in the following the air path from the powder groove 16 a to the mouthpiece opening is referred to as powder channel. It is, however, to be understood that the term “powder channel” does not necessarily refer to one distinct single powder channel but rather to a channel system as explained above.

As this can be taken from FIG. 2, the inhaler 1 includes a three-part housing comprising shells 12 and 13 as well as cover 14 received on the shells 12 and 13 via snap-fit connection in a non-releasable fashion.

The heart of the inhaler 1 is formed by a valve chamber 15 including the cyclone 16 and a cartridge body 3 a.

Manual operation of the inhaler 1 by a patient functions via dosage key 5 which on depression by the patient against the biasing force of a dosage key spring 17 acts on a dosage lever 6 which is connected to the dosage slide 8 (see FIG. 15).

Dosage slide 8 is slidably moveable within dosage slide passage 18 extending below the reservoir 2 within the cartridge body 3 a, as this for instance can be seen from FIG. 15.

The dosage slide 8 (metering means) includes a dosage cavity 19 for receiving a metered dose of a powdered drug.

It should be mentioned that the cartridge body 3 a not only defines the reservoir 2 for receiving the powdered drug but also defines a dosage slide passage 18 extending below the reservoir 2 as well as a housing for receiving counting and indexing means as this is described hereinafter more detailed.

The dosage slide 8 is shown in FIG. 15 in its emptying position where the dosage cavity 19 is aligned with an opening 20 in the valve chamber 15 communicating with the powder groove 16 a of the cyclone 16. The dosage slide 8 is moveable via dosage lever 6 between a filling position where the dosage cavity 19 is aligned with an opening 21 of the reservoir 2 within the cartridge body 3 a and an inhalation/emptying position. In the filling position, the dosage cavity 19 receives a metered quantity of powder. Upon actuation of the dosage key 5, the dosage slide 8 will be advanced into the position shown in FIG. 15, thereby releasing the powder dose into the powder groove 16 a through the opening 20.

In this position shown in FIG. 15, the inhaler is ready for inhalation. In the event the patient applies suction via mouthpiece 10, this forces a flap valve 22 at the very end of an air duct 9 to swing open so that an air flow can freely circulate from the open end of the air duct 9 into a powder channel defined by the valve chamber 15 and the powder groove 16 a of the cyclone, into the mouthpiece. The flap valve 22 includes the flap 22 a and a shaft 22 b which are in the disclosed embodiment integrally formed.

The flap valve 22 according to a first embodiment in more detail is shown in FIGS. 10 and 11 a. The shaft 22 b of the flap valve 22 at its ends is pivot mounted within valve chamber 15.

As this can be seen also from FIG. 15, in the inhalation position the flap valve 22 is engaged by a fastening hook 23 of the dosage lever 6.

A rear side view of the flap valve 22 is for instance shown in FIG. 10. The flap 22 has an angled/bent profile including three legs 22 c, 22 d and 22 e, the first leg 22 c in the mounting position being inclined towards the closing direction of the flap valve 22, the second leg 22 d being inclined rearwardly and the third leg 22 e extending in forward direction and approximately tangentially to the rotary movement of the flap valve 22.

On the rear side of the first leg 22 c of the flap 22 a, a latching rib 47 is provided which may be engaged by the fastening hook 23 of the dosage lever 6 in the inhalation position. The fastening hook 23 of the dosage lever 6 at its leading end is provided with a barbed projection 50 which has a sloping face 51. The flap valve 22 includes a flap valve lever 31 integrally formed with said shaft 22 b. The distal end of the flap valve lever 31 is provided with a deflector surface 53. Upon actuation of the dosage key 5 and subsequent actuation and downward movement of the dosage lever 6, a corresponding deflector surface 53′ of a latch 29 integrally formed with the hook 23 of the dosage lever 6 gets into abutment with the deflector surface 53 of the flap valve lever 31. The flap valve lever 31 as well as the hook of the dosage lever are thereby both being slightly deflected, i.e. bent aside and snap back in their initial position upon further downward movement of the hook 23 of the dosage lever 6. Upon further downward movement of the hook 23, the sloping face 51 of the barbed projection 50 abuts one edge of the latching rib 47. Thereby the hook 23 is bent aside due to the resilience of its material and snaps back behind the latching rib 47 in its end position thereby engaging the flap valve 22 and being releasable by an inhalation-triggered pivoting movement of the flap valve 22.

As this can particularly seen from FIG. 14 b, which shows an enlarged longitudinal cut through the flap 22 a, the barbed projection 50 of the hook 23 engages the latching rib 47. When the inhaler 1 is ready for inhalation, the latching rib 47 includes a curved bearing surface 54 facing the barbed projection 50. The bearing surface 54 which defines a cam surface almost providing line contact between the barbed projection 50 of the hook 23 and the latching rib 47 so that the contact force between the latching rib 47 and the hook 23 is almost independent from the tolerances of the components. To be more specific, the planar surface of the barbed projection 50 of the hook engages the curved bearing surface 54 only tangentially so that in effect excursion of the contact surface due to tolerances of the parts of the inhaler is only possible in axial direction, which, however, has no impact on the required triggering forces. Due to this design the required triggering forces are only subject to minor variations so that triggering of the flap valve 22 is fairly reproducible. It is readily apparent from FIG. 15 that if the flap 22 a moves in clockwise direction, the hook 23 is released almost instantaneously. As a result, the dosage lever may swing upwards driven by the force of the dosage lever spring 25. This upward movement will cause the dosage slide 8 to return to its powder receiving position.

Another embodiment of the flap valve 22 is shown in FIGS. 11 b and 14 c. Same parts of the flap valve 22 are denoted by the same reference numerals.

The flap valve 22 according to this embodiment comprises a relatively simple flat flap 22 a which is not bent or angled in itself.

As this can be taken from FIG. 14 c, the fastening hook 23 engages the shaft 22 b of the flap valve 22 when the inhaler 1 is ready for inhalation.

The shaft 22 b of the flap valve 22 (see for instance FIG. 11 b) has a cut out area 24 which is arranged approximately in the middle of the shaft 22 b such that, if the flap 22 a swings open (in FIGS. 14 c and 11 b in clockwise direction), the fastening hook 23 of the dosage lever 6 tangentially engaging the shaft 22 b approximately in the middle of the shaft 22 b, will be released so that the dosage lever 6 driven by the force of the dosage lever spring 25 may return to its initial position, thereby moving the dosage slide 8 back into the filling position for receiving a powdered dose from the reservoir/powder cartridge. Upon actuation of the dosage key 5 the dosage lever 6 will be moved downward while partially pivoting the flap 22 a by contact of the latch 29 of the dosage lever 6 with the flap valve lever 31. After partially pivoting the flap valve 22 swivels back to its starting position by the force of its molded, integrally formed spring 32. The pivot motion of the flap 22 a caused by the contact of the latch 29 with the flap valve lever 31 allows the latch 29 to engage behind the mechanical stop 30 of the flap valve lever 31 upon early release and upward movement of the fastening hook 23.

In the area of the cut out portion 24 of the shaft 22 b, the shaft 22 b has only a semi-circle cross-section, the leading end of the fastening hook 23 engages the remainder of the cross-section of the shaft only tangentially and only in a very limited surface area (line contact) so that the contact force between the shaft 22 b and the fastening hook 23 is almost independent from the tolerances of the components. Due to this design, in particular due to the fact that a planar contact surface of the fastening hook 23 contacts a curved surface area of the remainder of the cross section of the shaft 22 b, the required triggering forces are only subject to minor variations so that triggering of the flap valve 22 is fairly reproducible. Only a slight rotation/pivoting movement of the shaft 22 b and the flap 22 a will set the fastening hook 23 free so that the dosage lever 6 may swing upwards driven by the force of the dosage lever spring 25, thereby finishing the inhalation cycle.

A perspective view of the dosage key 5 is shown in FIG. 5. The dosage key 5 is held in its initial position/starting position by dosage key spring 17 which abuts a tongue member 26 integrally formed with the dosage key 5.

Said dosage key 5 includes an actuator blade 27 being formed as a flexible arm/leg also integrally formed with the dosage key 5 and extending downwards in the mounting position shown in FIG. 5. As this can be seen from the operating sequence shown in FIGS. 6 to 8 a, valve chamber 15 is provided with a beveled edge 28 forming a kind of cam surface for the actuator blade 27 upon depression of the dosage key 5.

FIG. 6 shows a cross-sectional cut through the inhaler 1 where the dosage key 5 is in its not-operated starting position. The actuator blade 27 in this state is not engaged with the transportation mechanism, i.e. with the dosage lever 6.

Upon depression of the dosage key 5, the actuator blade 27 moves downwards and engages the beveled edge 28 of the valve chamber such that the actuator blade 27 due its inherent flexibility is deflected/bent from a first position shown in FIG. 6 to a second position in FIG. 7 a where it engages at the same time the dosage lever 6. By a further movement of the dosage key 5 and the actuator blade 27, the actuator blade 27 urges the dosage lever 6 downwards against the biasing force of dosage lever spring 25. Upon full depression of the dosage key 5, which is shown in FIG. 8 a, actuator blade 27 snaps back in its non-deflected and disengaged position. In this position the fastening hook 23 of the dosage lever 6 engages the latching rib 47 of the flap valve 22 as this is also shown in FIG. 8 a. The device/inhaler is now ready for inhalation.

In the following the double dosing prevention mechanism of the inhaler according to the invention will be described, first referring to the first embodiment of the flap valve 22 according to the invention.

As this has been mentioned before, the dosage lever 6 in the area of its trailing end (left hand side in FIG. 9) is provided with latch 29. Upon downward movement of the dosage lever as a result of the actuation of the dosage key 5, first of all the complementary deflection surface 53′ of the latch 29 gets into abutment with the deflector surface 53 of the flap valve lever 31. As a result, the flap valve lever 31 is bent aside/deflected while being passed by the fastening hook 23 and snaps back into its initial position upon further downward movement of the dosage lever 6, which ultimately will result in engagement of the hook and the latching rib 47.

It is again referred to FIG. 9 which shows a perspective view of the dosage lever 6. In the area of its trailing end (left hand side in FIG. 9), the dosage lever 6 is provided with a latch 29 for engaging a mechanical stop 30 of a flap valve lever 31 integrally formed with said shaft 22 b on a return movement of the dosage lever 6.

In the event the dosage key 5 will be pressed and released too early, i.e. prior to the engagement of the fastening hook 23 into the latching rib 47 of the flap valve 22, latch 29 of the dosage lever 6 upon upward movement of the dosage lever 6 will abut said mechanical stop 30 of the flap valve lever 31. Accordingly, the dosage lever 6 locks into the flap valve 22 in a middle position. This middle position lock provides a double dosing prevention mechanism. In this middle position lock, i.e. first locked position, the relationship of lever is such that the forces required for releasing the dosage lever 6 can not be brought up simply by inhalation. If the dosage lever 6 does not lock into flap valve 22 in the end position, e.g. when the dosage key 5 is not pressed all the way down, the dosage lever 6 will not return to its initial starting position, i.e. will be locked in the middle position. Accordingly, no additional powder dose will be released from the reservoir 2. The dosage lever 6 and the dosage slide 8 will only return into their starting position after inhalation-triggered actuation of the flap valve 22, thereby releasing the fastening hook 23 of the dosage lever 6.

A double-dosing prevention mechanism is also provided with the design of the flap valve 22 of the second embodiment according to FIG. 14 c. Upon actuation of the dosage key 5, the dosage lever 6 will be moved downward while partly pivoting the flap 22 a by contact of the latch 29 of the dosage lever with the flap valve lever 31. After partly pivoting the flap upon downward movement of the dosage lever, the flap valve 22 will return into its closed position due to the resilience of a spring 32 integrally molded with the flap valve 22. Latch 29 of the dosage lever 6 upon an early upward movement of the dosage lever 6 will abut the mechanical stop 30 of the flap valve lever 31. Accordingly, the dosage lever 6 locks into the flap valve 22 in a middle position.

Dosage lever 6 includes a cam-like actuating element 33 which upon each actuation moves a counter slide 34 of the cartridge so that a counter ring 35 of the cartridge is moved by one count towards a lower dose. The degree of the cartridge's content is accordingly visible in a display window 36 of the cartridge body 3 a indexing the fill status of the cartridge. Details of the counter slide 34 acting on the counter ring 35 may be taken from FIG. 18. Counter ring 35 which is designed as a ratchet ring with teeth 37 is rotably inserted into a collar of the cartridge body 3 a. Upon actuation of the dosage lever 6, the actuating element 33 moves the counter slide 34, the counter slide engaging the counter ring's teeth 37, thereby moving the counter ring 35 so that the next index number is indicated in the display window 36. The counter ring 35 for instance provides a visual indication of a dose count for each 5^(th) dosing step/metering cycle. The counter ring for instance shows thirteen numbers and indicates a countdown from 60 to 0 upon each metering cycle. Each tooth of the counter ring 35 represents one metering cycle.

As this also can be taken from FIG. 4, the counter slide 34 includes a pawl 43 integrally formed with the counter slide 34. The pawl 43 is biased towards the counter ring 35 that it firmly engages the teeth 37 of the counter ring 35. The teeth 37 are unsymmetrical insofar as they have one sloping flank and one vertically extending flank, the sloping flank representing the leading flank with respect to the rotational direction of the counter ring 35.

The counter slide 34 is moveable back and forth within a sliding channel 44 of the cartridge body 3 a. The cam-like actuating element 33 of the dosage lever 6 extends into the sliding channel 44 and into a recess 45 of the horizontally extending part of the counter slide 34. Engagement of the actuating element 33 with the counter slide 34 transforms a pivoting movement of the actuating element 33 into a linear movement of the counter slide 34.

Upon depression of the dosage key 5, the dosage lever will be pivoted such that the actuating element 33 is pivoted towards the left hand side in FIG. 4. At the same time, the lower leading end 46 of the dosage lever (see FIGS. 9 and 12) pushes the dosage slide 8 into its emptying/inhalation position. The counter slide 34 is thereby moved in the opposite direction. While the counter slide 34 fulfills this movement, the pawl 43 engages the vertical flank of the respective tooth 37 of the counter ring, moving the counter ring one count/step. After release of the dosage lever 6, the counter slide 34 will be moved backwards into its starting position. Due to the resilience of the pawl 43, the pawl may glide over the sloping flank of the respective tooth, thereby snapping back behind the tooth. As this can be seen from FIG. 19, the counter mechanism includes a locking ratchet 38 engaging the counter ring teeth 37. Due to the geometry of the teeth 37, the locking ratchet 38, which is also a resilient member, blocks an anti-clockwise rotation of the counter ring 35.

As this can be seen from FIG. 12, the inhaler 1 includes a locking lever 7 which is pivotably mounted in the valve chamber 15 between dosage key 5 and dosage lever 6. The locking lever 7 includes a blocking arm 39 and a spring leg 40. During assembly of the powder cartridge 3, the locking lever 7 is pushed downwards, the blocking arm 39 and the spring leg 40 thereby being moved backwards. In this position, the dosage key 5 may be freely moved downwards against the biasing force of the spring leg 40 as shown in FIG. 12.

The dosage key 5 is also freely moveable against the biasing force of the dosage key spring 17 as shown in FIG. 15.

The counter ring 35 includes a notch 41 being engageable by a tongue 42 of the locking lever 7.

The notch is arranged on the counter ring 35 such that, after a pre-determined number of doses has been delivered, the locking lever 7 engages the notch in the counter ring with a pivoting movement caused by the action of spring leg 40 actuated by the dosage key 5. Upon upward movement of the locking lever 7, the blocking arm 39 of the locking lever 7 is pushed forward (towards the mouthpiece 10) and engages the dosage key 5 in its lowest position such that the dosage key 5 stays blocked in its lowest position after the last inhalation. It is impossible to perform another activation of the empty device.

As this can be seen from FIGS. 5 and 20, the dosage key 5 includes an actuation rib 55 acting on the spring leg 40 only while being in depressed condition in order to avoid fatigue of the spring leg 40. The spring leg 40 is accordingly only biased if the dosage key 5 is being pressed or held downward.

Apart from the indexing means in the form of the counter ring, the device includes another inhalation control window 48 indexing whether the device is ready for inhalation or not. The inhalation control window shows for instance a green-colored flag in the event the device is ready for inhalation. This is because in the activated status of the inhaler 1 a green colored tab 49 of the dosage lever 6 covers a red colored flag in the inhalation control window 48. The reset of the device from the inhalation position into the starting position takes place during inhalation by means of an airflow upon inhalation. Flap valve 22 is deflected thus releasing the dosage lever 6 as this has been described in detail before.

In order to ensure leak tightness of the air duct 9, the shells 12 and 13 may be sealed against valve chamber 15 by means of one or more sealing ribs which extend around valve chamber 15. The sealing rib may be in form of a thermoplastic elastomer which has been co-injection molded with valve chamber 15. Alternatively, the sealing rib 52 may be designed as a resilient ring which has been mounted into a sealing groove during assembly of the inhaler.

In a particularly preferred embodiment of the inhaler according to the invention, the shells 12 and 13 are sealed against the valve chamber by a labyrinth seal which completely extends around the valve chamber 15, so that the valve chamber 15 including the cyclone 16 and the powder groove 16 a is effectively sealed against the dosing compartment of the inhaler. The labyrinth seal is provided by a sealing rib 52 completely extended around the valve chamber 15 and in the assembled state of the inhaler 1 engaging a corresponding sealing groove in the shells 12 and 13. This sealing assists in keeping the triggering forces for the flap valve 22 as reproducible as possible. The bandwidth for the required triggering forces normally corresponds to an air flow variation of 30 l/min for the suction to be applied by the patient. Sealing the valve chamber of the inhaler 1 against the shells 12, 13 remarkably reduces this variation in required air flow for triggering the flap valve 22. Accordingly, this design avoids the possibility of sucking an air flow through the inhaler which bypasses the powder channel and/or the air duct 9.

REFERENCE NUMERALS

-   1 inhaler -   2 reservoir -   3 cartridge -   3 a cartridge body -   4 lid -   5 dosage key -   6 dosage lever -   7 locking lever -   8 dosage slide -   9 air duct -   10 mouthpiece -   11 mouthpiece cap -   12, 13 shells -   14 cover -   15 valve chamber -   16 cyclone -   16 a powder groove -   17 dosage key spring -   18 dosage slide passage -   19 dosage cavity -   20 opening -   21 opening -   22 flap valve -   22 a flap -   22 b shaft of flap valve -   22 c first leg of flap valve -   22 d second leg of flap valve -   22 e third leg of flap valve -   23 fastening hook -   24 cut-out portion -   25 dosage lever spring -   26 tongue member -   27 actuator blade -   28 beveled edge -   29 latch -   30 mechanical stop -   31 flap valve lever -   32 spring of flap valve -   33 actuating element -   34 counter slide -   35 counter ring -   36 display window -   37 teeth -   38 locking ratchet -   39 blocking arm -   40 spring leg -   41 notch -   42 tongue -   43 pawl -   44 sliding channel -   45 recess -   46 leading end of dosage lever -   47 latching rib -   48 inhalation control window -   49 tab -   50 barbed projection -   51 sloping face -   52 sealing rib -   53 deflector surface -   53′ deflector surface -   54 bearing surface -   55 actuation rib 

1. Inhalation device for powdered drugs to be received by a patient by an inhalation-caused air stream, comprising at least one powder reservoir, metering means for repeatedly metering a powder dose from the reservoir, a transportation mechanism for moving said metering means from a filling position for receiving a powder dose into an emptying position for releasing said powder dose into a powder channel, at least one activating device for manual operation by the patient, said activating device being operatively connected to said transportation mechanism such that upon operation a single powder dose is being metered, said activating device comprising a dosage key acting on said transportation mechanism when pressed by the patient, said transportation mechanism comprising a dosage lever acting on said metering means, wherein said dosage lever is locked in the inhalation position of said metering means after said dosage key has been actuated by the user, wherein said dosage lever in the inhalation position engages a trigger member and is releasable by actuation of the trigger member, wherein the trigger member comprises at least one cam surface and wherein the dosage lever engages said cam surface tangentially in said locked inhalation position.
 2. Inhalation device according to claim 1, characterized in that said trigger member comprises an inhalation-operated valve in an air duct communicating with said powder channel.
 3. Inhalation device according to claim 1, characterized in that the dosage lever comprises a fastening hook engaging behind and/or under said cam surface in the inhalation position.
 4. Inhalation device according to claim 1, characterized in that the fastening hook comprises a planar contact surface making line contact with the cam surface in the inhalation position.
 5. Inhalation device according to claim 1, characterized in that triggering of the dosage lever is achieved by a pivot motion of the cam surface.
 6. Inhalation device according to claim 1, characterized in that said inhalation-operated valve includes a flap which fulfils a pivot movement upon inhalation, said cam surface being provided on the flap or on a pivot shaft of the flap.
 7. Inhalation device according claim 1 further comprising at least one powder disintegration means, wherein said metering means and said transportation mechanism are arranged within a dosing compartment and said disintegration means is arranged in a powdered discharge compartment, and wherein said dosing compartment is sealed against said powder discharge compartment.
 8. Inhalation device according to claim 7 comprising a main structural support member defining a valve chamber as well as a support for a housing including at least two shells.
 9. Inhalation device according to claim 8, characterized in that the valve chamber is sealed against the housing so as to define said dosing compartment and said powder discharge compartment.
 10. Inhalation device for powdered drugs to be received by a patient by an inhalation-caused air stream, comprising at least one powder reservoir, metering means for repeatedly metering a powder dose from the reservoir, a transportation mechanism for moving said metering means from a filling position for receiving a powder dose into an emptying position for releasing said powder dose into a powder channel, at least one activating device for manual operation by the patient, being operatively connected to said transportation mechanism such that upon operation a single powder dose is being metered, said activating device comprising a dosage key acting on said transportation mechanism when pressed by the patient, the inhalation device further comprising at least one powder disintegration means, wherein said metering means and said transportation mechanism are arranged within a dosing compartment and said disintegration means is arranged in a powder discharge compartment, and wherein said dosing compartment is sealed against said powder discharge compartment.
 11. Inhalation device according to claim 10, further comprising a main structural support member defining a valve chamber as well as a support for a housing including at least two shells.
 12. Inhalation device according to claim 11, characterized in that the valve chamber is sealed against the housing so as to define said dosing compartment and said powder discharge compartment. 